Container sealing machine



April 15, 1969 G.J.Foss ET AL 3,438,174

CONTAINER SEALING MACHINE Filed Feb. 11, 1955 Sheet of 12 L0 N 1 m HTTOrP/YC) April 15, 1969 J, 055 ETAL CONTAINER SEALING MACHINE Sheet Filed Feb. 11. 1965 INVENTORS Gm d. Foss BY dosc' fl C. Pun co C6C/L 7S ATI'OQYC? April 15, 1959 G. J. Foss E AL CONTAINER SEALING MACHINE Sheet Filed Feb. 11. 1965 INVENTORS 6' J7 Foss 50 3 BY Jose h C. Faxvco Cccm F? fFbec w-s I977'OQV V April 15, 1969 J, Foss ET AL CONTAINER SEALING MACHINE Filed Feb. 11, i965 Sheet 4 of 12 C gg/vco nmmkwj HTTOPMSY INVENTORS (960966 J Foss BY JOSEPH w I E 4 M April 15, 1969 F055 ET AL 3,438,174

CONTAINEh SEALING MACHINE Filed Feb. 11, 1955 Sheet 5 of 12 INVENTORS m. (l. fc'ass BY UOSEP/v C- P wco Y Ceca. f? P056075 YIMWKSY Ma April 15, 1969 F055 ET AL CONTAINER SEALING MACHINE Filed Feb. 11, 1965 Sheet INVENTORS Sheet 7 of 12 CRUNCO E 1971 MM AWN 5 INVENTORJ GEOQGEJjF'ETSs JOSE PH O0 C Ecu. F?

G. J. FOSS ET AL CONTAINER SEALING MACHINE A ril 15, 1969 Filed Feb. 11, 1965 O O :1 k

April 15, 1969 G. J. FOSS ET AL 3,438,174

CONTAINER SEALING MACHINE Filed Feb. 11. 1965 Him? ",fflli INVENTORS 6150961: 1 Foss BY JOSEP/l C. Po /co Ccc/z. P 4 060976 AITOP/Vc'y G. J. FOSS ET AL CONTAINER SEALING MACHINE A ril 15, 1969 Sheet Filed Feb. 11. "1965 m T N E V m Geo/9G6 1 Foss BY dost/ H C lPuzvco C6 /c. P mm mm April 15, 1969 J, F055 ET AL CONTAINER SEALING MACHINE BY CcC/L. F? I WWW Filed Feb. 11. 1965 April 15, 1969 J. Foss ET AL 3,438,174

CONTAINER SEALING MACHINE Sheet ll of 12 Filed Feb 11, 1965 April 15, 1969 i Fo s ET AL 3,438,174

CONTAINER SEALING MACHINE Filed Feb. 11, 1955 Game d. Foss BY (/OSfiP/l C fb/vco C60. I? 9356 973 WW3? WW United States Patent 3,438,174 CONTAINER SEALING MACHINE George .I. Foss and Joseph C. Runco, Lancaster, and

Cecil P. Roberts, Carroll, Ohio, assignors to Anchor Hocking Glass Corporation, Lancaster, Ohio, a corporation of Delaware Filed Feb. 11, 1965, Ser. No. 431,953

Int. Cl. 1365b 31/02 US. Cl. 53-110 12 Claims ABSTRACT OF THE DISCLOSURE A sealing machine for sealing containers with closure caps and including a conveyor belt which carries the filled containers successively beneath a cap feeding and applying means and then a sealing head which fastens the closure cap onto the container top. The cap feeding and applying means as well as the sealing head are all mounted on a unitary support which also mounts side belts for engaging and carrying the containers past the cap feeding and applying means and sealing head. The support also includes a hollow steam chamber which extends around the cap feeding and applying means and the sealing head and which also telescopes downwardly around the conveyor for the purpose of containing a steam atmosphere during the sealing operation for forming a vacuum in the sealed container. All of the above elements of the machine are incorporated in a unitary structure so that their height is simultaneously adjusted with respect to the container supporting conveyor and means is provided for retaining the necessary synchronism between the driven portions including the sealing head, the side belts, and the conveyor belt during this adjustment. In addition an adjustable cap feed chute and improved back-up rollers are provided in the above described combination.

The present invention relates to the container sealing art and more particularly to an improved automatic container sealing machine.

The sealing machine of the present invention is of the general type wherein filled containers are passed through the machine in a straight line and wherein these filled containers are sealed with a closure cap during the passage and wherein a vacuum is formed in the sealed package Straight line sealing machines of this general type are known, however, improvements in operating speed and sealing efliciency have been accompanied by increases in the size and complexity of the machines. The machine of the present invention provides a novel structure for such a sealing machine providing improved sealing while at the same time permitting a substantial reduction in both the size and the complexity of the machine.

The novel machine structure, as will be more fully described below, obtains these improved results while at the same time providing a machine that is readily set up and adjusted for handling various types of closure caps and a wide variety of container shapes and sizes. The machine is also particularly adapted for use with existing conveyor systems as it incorporates the sealing elements in an independently supported and driven head structure.

It will be seen that these features combine in the new machine to provide a sealing machine adapted for substantially universal use and one particularly useful in sealing operations best served by relatively simple and inexpensive machines capable of being serviced by technicians of ordinary skill. It also provides a machine economically suitable for smaller packing installations wherein considerable savings in plant space and sealing costs result from the high-speed, small size, simplified main- 3,438,174 Patented Apr. 15, 1969 ice tenance, and easy adjustment inherent in the machine of the present invention.

Accordingly, an object of the present invention is to provide an improved container sealing machine.

Another object of the present invention is to provide a high-speed sealing machine of simplified form.

Another object of the present invention is to provide an automatic high-speed sealing machine characterized by compact form and requiring a minimum of space and useful with existing container conveyors.

Another object of the present invention is to provide an efiicient high-speed sealing machine which is readily adapted for a variety of container sizes and shapes and closure cap designs.

Another object of the present invention is to provide a high-speed automatic sealing machine with an improved synchronized drive system.

Other and further objects of the invention will be obvious upon an understanding of the illustrative embodiment about to be described or will be indicated in the appended claims, and various advantages not referred to herein will occur to one skilled in the art upon employment of the invention in practice.

A preferred embodiment of the invention has been chosen for purposes of illustration and description and is shown in the accompanying drawings, forming a part of the specification, wherein:

FIG. 1 is a front elevational view partially cut away illustrating a preferred embodiment of the sealing machine of the present invention;

FIG. 2 is a top plan view of the machine of FIG. 1;

FIG. 3 is a side elevational view of the container entrance end of the machine of FIG. 1;

FIG. 4 is a perspective view illustrating the sealing machine head with the steam chamber removed;

FIG. 5 is a fragmentary front elevational view partially cut away of the sealing machine head including the cap applicator and cap sealing unit;

FIG. 6 is a top plan view partially cut away of the sealing machine head corresponding to FIG. 5;

FIG. 7 is a sectional view of the sealing machine taken along line 7-7 of FIG. 5;

FIG. 8 is an enlarged detailed sectional view of the side belt back-up bars;

FIGS. 9 and 10 are enlarged sectional views of the cap chute taken along lines 9-9 of FIG. 1 and 1010 of FIG. 9 respectively.

FIG. 11 is an enlarged detailed perspective view partially in section of the lower end of the cap chute and of the cap applicator;

FIG. 12 is a side elevational view of the chute end and cap applicator of FIG. 11;

FIGS. 13 and 14 are enlarged sectional views of the cap applicator taken along lines 1313 and 14-14 of FIG. 12;

FIG. 15 is a top plan view of the container side belts and the side belt back-up bars;

FIG. 16 is an enlarged perspective view of a preferred embodiment of the sealing unit;

FIG. 17 is a perspective view of another embodiment of the sealing machine with a modified drive system;

FIG. 18 is an enlarged fragmentary rear elevational view illustrating the sealing head drive on the machine of FIG. 17;

FIG. 19 is a side elevational view of the head drive of FIG. 18;

FIG. 20 is a fragmentary rear elevational view of another embodiment of the sealing machine illustrating a chain connected conveyor;

FIG. 21 is a fragmentary top plan view of the machine of FIG. 20; and

The embodiment of the sealing machine as illustrated in FIG. 1 at 1 includes a moving conveyor 2 which carries filled container 3 between a pair of driven side belts 4. The container 3 thus gripped -is carried beneath the end of an inclined cap feed chute 5 which presents an inclined closure cap 6 to the top of the moving container 3 so that the container 3 draws the cap 6 out of the chute 5 into telescoping relationship with its rim. Thereafter a cap applicator 7 levels the cap 6 on the container rim and in the case of a screw cap lightly coaxes it onto the container threads. The container 3 is then moved beneath a sealing unit 8 which presses the cap down into tightly sealed engagement with the container finish and for screw caps simultaneously twists it onto the container threads.

As seen in FIG. 1, the cap applicator 7 and the sealing unit 8 are mounted within a hollow chamber 9 and the chamber 9 includes steam outlets 10 (FIG. 5) which direct steam into the container 3 headspace prior to the application of the cap 6 and which also maintain a steam atmosphere about the container top as the container 3 is moved beneath the applicator 7 and the sealing unit 8. This causes steam to be trapped within the sealed container whereby its subsequent condensation creates a vacuum in the containers.

The side belts 4, the applicator 7, and the sealing unit 8 together with the chamber 9 and the associated drives and steam controls comprise the sealing machine head.

Conveyor and head support and drive means As best illustrated in the front, top, and side views of the machine in FIGS. 1, 2 and 3, the improved sealing machine is characterized by a central support column 11. The column 11 includes a broad base extending a substantial distance in the direction of the conveyor belt and also extending toward the front of the machine as shown in FIG. 3 to provide a substantial portion of the machines support including the entire support for the sealing machine head. A frame 12 for the conveyor belt 2 is adjustably mounted on the column 11 by an adjustable bracket 13. The opposite ends of the conveyor frame 12 are stabilized by auxiliary adjustable support posts 14 coupled to the frame adjacent to the conveyor end pulleys 15.

The sealing machine head as indicated above includes the chamber 9 having the applicator 7 mounted on an inner wall by a suitable bracket 15 and the sealing unit 8 adjustably mounted from the chamber 9 by a pair of brackets 16. In addition, the side belt end pulleys 17 and 18 together with the side belt back-up bars 19 and 20 (FIG. 15) are also mounted on the opposite ends of chamber 9.

As seen in FIG. 3, the chamber 9 is also slidably mounted on the column 11 on the bracket bearing 21 permitting the entire assembly including the side belts 4, the applicator 7, and the sealing unit 8 to be adjusted vertically simultaneously by the single height adjustment provided for the chamber 9. This height adjustment includes a vertical screw 22 rotatably mounted on a clamp 23 and threadedly coupled to the bracket bearing 21 at 24. The screw 22 is rotated by a suitable crank 25 mounted on a post clamp 26 and operatively connected to the screw 22 through right-angled gearing.

It will be seen that rotation of the crank 25 in one direction or the other will provide for the adjustment of the height of the sealing machine head including the side belts 4, the applicator 7, and the sealing unit 8, thus permitting the sealing machine to be readily adjusted for sealing containers of the varying heights and without requiring independent adjustments of these elements.

The conveyor frame 12 height may also be adjusted using the adjustable bracket 13 on the column 11 together with compensating adjustment of the conveyor end posts 14.

The sealing machine drive system It will be seen from the above general description that there are three cooperating moving elements all of which engage the containers 3 during the sealing operation. These include the conveyor 2 and the side belts 4 which are driven at the same speed so that they cooperate to move, support, and grip the filled containers 3 and a sealing belt 30 (FIG. 5). For press-on caps, the sealing belt 30' is also driven at conveyor speed and for screwtype caps the belt 30 is preferably driven faster than the containers 3 so that it engages an off-center portion of the caps previously applied to the containers and simultancously presses and rotates the caps into sealing engagement with the container finish and threads as will be more fully described below in a description of a preferred embodiment of a sealing unit 8 for screw-type closure caps.

A novel drive system is provided including a single drive motor 31 conveniently mounted on end post 14 and preferably a variable speed electric motor controlled by a suitable electrical motor control 32. The conveyor 2 is driven at the desired speed through the intermediation of a connection to the motor including sprockets 33 and 34 and chain 35.

The side belts 4 are driven at the same speed as the conveyor 2 through a positive coupling between the front pulleys 17 for side belts 4 and the drive shaft 27 for the conveyor 2 drive pulley 15. As best illustrated in FIG. 2, this coupling includes a right angle coupling 29 between the shaft 27 and a head drive shaft 28, such as a helical gear coupling. A similar right angle coupling 36 at the upper end of the head drive shaft 28 connects the shaft 28 to a horizontal head drive shaft 38. A helical gear coupling 37 drives the two side belt pulleys 17 through support shafts 39. In order to permit the above described height adjustment of the head, the portion of the geared coupling 36 at the upper end of the head drive shaft 28 is splined to the shaft 28 permitting it to slide lengthwise of the shaft 28 to compensate for changes in height of shaft 38. The housings for the two couplings 29 and 36 rotate on their respective shafts 27 and 38 to permit the height adjustment. The sealing belt 30 is driven at its desired speed through a suitable positive coupling to the horizontal drive shaft 38. The preferred embodiment illustrated in FIG. 6 comprises a chain 49 connecting sprocket 41 on the horizontal shaft 38 to the sprocket 42 mounted on ,a belt drive shaft 43 which drives the forward sealing belt pulley 44.

It is clear that the above described positive connections permit simultaneous speed adjustments of all driven elements by the adjustment of the motor speed and also permit adjustment of the machine head height for sealing containers of differing heights while maintaining the necessary synchronization between the various driven elements.

Sia'e belt mounting As indicated above, the two side belts 4 which engage each container 3 to facilitate its movement past the cap applicator 7 andthe sealing unit 8 are mounted on the sealing machine head so that the heights of the belts 4 are simultaneously adjusted with the adjustment of the height of the head.

The support means for each of the belts 4 is illustrated in FIGS. 6, 8 and 15 and include the front pulleys 17 mounted on and driven by the vertical shafts 39 as described above. The vertical shafts 39 are supported by a bearing bracket 45 mounted on or formed integrally with the chamber 9. A rear pulley 18 is provided for each of the side belts 4 and is adjustably positioned lengthwise of the conveyor 2 in a slot 47 in the mounting bracket 48. The mounting brackets 48 are attached to the end of the back-up bars 19 and so that their position laterally of the conveyor 2 is adjusted with the position of the back-up bars 19 and 20.

The back-up bars 19 and 20 are adjustably mounted on the head 9 for movement transversely of the conveyor 2 to adjust the side belt spacing for containers 3 of differing diameters. Both bars 19 and 20 are slidably mounted on horizontal support tracks 49 (FIG. 6). The support tracks 49 each support an elongated adjustment screw 50 controlled by a knob 51 conveniently positioned at the front of the sealing machine. The back-up bar 19 has a discharge end support bracket 52 (FIG. 15)

and an intake end support bracket 48 slidably connected to the tracks 49 at slots 53 (FIG. 6) in the tracks 49. The rear back-up bar 20 has its support brackets 54 and 48 slidably coupled to the support tracks 49 through the intermediation of slots 55 and 56. The brackets 48, 52, and 54 are coupled to the oppositely threaded portions 57 and 58 of the adjusting screws 50 through the intermediation of the threaded connecting arms or nuts 59 (FIG. 6). Rotation of the control knobs 51 is thus seen to provide for a controlled adjustment of the spacing of the side belts 4 while maintaining the containers 3 in a central position on the conveyor 2 and with respect to the cap applicator 7 and the sealing head 8.

The preferred embodiment of the back-up bars is best illustrated in FIGS. 8 and 15. Each of the bars 19 and 20 is seen to include an elongated base 60 which cooperates with upper and lower flange members 61 to provide an inwardly facing channel 62. The inner surface of this channel is lined with a non-metallic liner 63 which may be a plastic or a rubber-like back-up material and which engages an elongated roller guide 64 for each of the side belts 4. The roller guides 64 provide a side belt positioning and friction reducing means to control the contact between the belts 4 and the containers 3.

As best seen in FIG. 15, the roller guides 64 are disposed in the channel 62 between an entrance fastener 65 and an exit fastener 66. The preferred embodiment of the roller guide itself includes a plurality of small rollers 67. In order to provide flexibility to conform the roller guides 64 to the channels 62, each pair of rollers 67 are preferably rotatably mounted in upper and lower flared guide plates 68 and the pairs of guide plates 68 are coupled together by pivoted links 69. As best seen in FIG. 8, the belt contacting surfaces of the flared guides 68 support the belts 4 and position them with their inner surfaces in engagement with the rollers 67. One or the other of the guide plates 68 may be omitted in some cases and it is also possible to use rollers having belt guiding flanges at their ends.

As indicated above, the sealing machine of the present invention may have a steam atmosphere within the chamber 9 to provide a vacuum seal. In order to maintain steam within the chamber, the outer edges of the back-up bars 19 and 20 include a cover section 70 (FIG. 8) which cooperates with the lower portions of the chamber 9 to provide a sealing surface lengthwise of the chamber 9. In addition, bottom covers 71 are adjustably connected to the back-up bars so that they extend downwardly alongside of the conveyor 2 a suitable distance to further define the steam zone. The lower covers 71 have spaced cars 72 with slots 73 disposed transversely of the sealing machine to permit a lateral adjustment of the covers 71 when the back-up bars 19 and 20 are adjusted to accommodate containers of a particular size. This adjustable connection between the back-up bars 19 and 20 and lower covers 71 includes a support angle 74 bolted to the side bar 19 or 20 and a slidable coupling 75 between the lower leg of the angle 74 and the slots 73 in the ears 72.

The above described adjustments of the side belts 4 are facilitated by a removable front panel 76 which slides under the top of the chamber 9 and which has its bottom positioned at the cover 70 on the front back-up bar 19 and which is also detachably connected to the head 9 by knobs 77 (FIG. 1).

The cap feed As indicated above caps 6 are fed down an inclined cap chute 5 from a cap hopper 80 which provides a continuous supply of caps 6 positioned with their tops facing upwardly. Suitable hoppers are available for this purpose and the hopper itself does not constitute a part of this invention. Suitable hoppers and related aligning devices for providing continuous supply of caps to the chute are described, for example, in United States Patents Nos. 2,863,588, and 3,065,841 owned by the assignee of the present invention.

The hopper 80 is most conveniently mounted on a separate adjustable support 81 permitting adjustment of the height of the lower end of the cap chute '5 to conform to the particular height of the applicator 7 for a specific container 3. The cap chuts 5 directs the closure caps 6 from the hopper 80 to a position in advance of the cap applicator and above the conveyor 2 as best illustrated by the cap 6 in FIG. 11. In this position, the cap holding detents 83 at the outer edges of a pair of adjustably spaced end rails 84 hold the cap until a moving container 3 engages the cap and draws it over or through the detents 83 into telescoping relationship with the top of the moving container 3.

A preferred embodiment of the cap chute 5 is illustrated in FIGS. 9, 10 and 11. As seen therein, the cap chute 5 comprises relatively rigid top and side members and 91 to provide the necessary mechanical rigidity for the cap chute. Within these members 90 and 91 the caps 6 themselves are fed downwardly through an inclined guide of adjustable width and height. The adjustable width is provided by the spaced side guides 92 adjustably mounted on bolts 93 and resiliently held at their inner adjusted position by springs 94. The adjustable height for the chute is provided by including an inner chute top member 95 adjustably spaced with respect to the chute bottom 96 by means of the bolts 97. The inner top 95 is resiliently held in its adjusted position by springs 98. In the preferred embodiment of the cap chute, hollow upper and lower rails 99 and 100 are provided. These perform the dual function of providing a low-friction rail support for the caps and also of distributing steam within the cap and against the outer cover to raise the cap temperatures and to thus soften the cap gaskets to facilitate the final sealing action. These hollow rails 99 and 100 have steam inlets 101 and 102 which pass the steam into their hollow center permitting the steam to be directed onto the desired portions of the caps through the outlets 103 and 104 in the upper and lower rails respectively.

It is thus clear that the above described chute has a novel construction which permits its ready adjustment for caps of widely differing diameters and heights and also provides a simplified steam heating means for use where it is desired to pre-heat the closure cap gaskets to soften the gaskets for the sealing action in the sealing unit.

The cap applicator After the moving containers 3 have picked caps from the lower end of the cap chute 5, it is necessary to correctly position the caps on the tops of the containers preparatory to the final sealing action. A preferred embodiment of a cap applicator is illustrated in FIGS. 11 thru 14 for use with screw-type closure caps. This applicator 7, as indicated above, is attached by a suitable bracket 15 to the chamber 9.

A pair of levelling plates 108 and 109 are resiliently mounted on a longitudinal frame 110. The first leveling plate 108 includes a magnet 112 for holding ferrous metal caps against the plate 108 and in level position preferably slightly above the container threads. As seen in FIGS. 11 and 12, the plate 108 has its opposite ends pivotally attached to two connecting rods 113 and 114 slidably attached to the frame 110. A spring 115 yieldably holds the plate 108 downwardly at the level set by the adjustable mounting post 113 and 114. The plate 108 is thus free to pivot or rise at either or both ends on the above described mounting. A friction drag 112' lightly engages an off-center portion of each cap top as the cap is drawn onto the container top and gives it an initial reverse twist to disengage the container threads and to help level the cap before the cap is coaxed onto the container threads. The second plate member 109 is provided to coax or lightly twist the caps onto the container threads. For this purpose it includes a non-friction surface 116 and a drag 117. These adjustably spaced members 116 and 117 contact spaced portions of the moving cap 6 to coax or screw it lightly downwardly onto the container threads. The member 109 is also yieldably mounted on the frame 110. The plate member 109 is adjustably and rigidly positioned on a mounting plate 118 by connecting bolts 119 and a hold down screw 120. The mounting plate 118 is floatingly mounted on the end of the frame 110 by three guide posts 121 which permit the mounting plate 120 to lift as necessary against the hold down springs 122. An additional drag member 123 is positioned beyond the member 109 to retain the cap 6 in its coaxed position until it reaches the sealing unit 8 which provides the final sealing force.

Where the sealing machine is being used with press-on caps of the type which do not have threads and which are pressed dwownwardly over a container bead, the drag member 117 is not used and the members such as 108 and 109 have non-friction surfaces which first level caps in a horizontal position on the container finish and lightly press or wipe the caps against the container finish preparatory to a final downward sealing action at the sealing unit.

The steam outlets 10 are positioned adjacent the lower end of the cap chute and along the applicator 7. A hollow manifold 124 fed through steam inlet 125 supplies steam to the outlets 10.

The sealing unit As described above, the sealing head includes a sealing unit 8 within the chamber 9. This unit provides the final sealing force to press caps downwardly onto the containers and in the case of screw-type caps it simultaneously forces these caps down and rotates them into their final sealed position.

A preferred embodiment of a sealing unit 8 for screwtype caps with threads or lugs is illustrated in FIGS. 5, 6 and 16. The container leaving the applicator 7 and with a cap 6 lightly turned into engagement with the container threads is passed under the sealing unit 8 which simultaneously forces the cap down and turns it to its final sealed position. Two cooperating elements are used in the preferred sealing unit to obtain this action.

As best illustrated in FIG. 16, a drag shoe 130 having a lower friction surface 131 is positioned to engage a marginal area of the near side of the closure cap to provide a drag force rotating the cap in the applying di rection on the container threads while also pressing the cap down. The moving belt 30 is positioned by a hold down shoe 133 at an opposite marginal portion of the cap and is driven by the pulley 44 at a speed greater than that of the moving container whereby it also urges the cap to rotate downwardly on the container threads. It is thus clear that the drag shoe 130 and the belt 30 cooperate to provide a simultaneous downwardly directed and rotating force on opposite margins of the cap to turn the cap onto the container threads.

In the preferred embodiment, the drag 130 and the hold down plate 133 for the belt 30 are attached to the chamber 9 of the sealing machine head through the intermediation of a frame 134 mounted on a pair of spaced brackets 16.

FIG. 7 illustrates a preferred connection for the mounting brackets 16. The hollow upper portion 145 of the brackets 16 are threadedly connected at 146 to the chamber 9 and the lower portion of the brackets 16 which are slidably fitted in upper portions 145 are urged downwardly by springs 147 whose force is controlled 'by the threaded knobs 148. The vertical positions of the drag shoe and the belt 30 are simultaneously adjusted relative to the chamber 9 by adjustment of the threaded support portions on the chamber 9.

The attachment of the drag shoe 130 and the sealing belt 30 hold down plate 133 with the frame 134 preferably comprise a hinged member 136 which is pivotally mounted to permit the drag shoe 130 and the hold down plate 133 to rock about an axis directed longitudinally of the conveyor and to thus permit the belt 30 and the drag shoe 130 to automatically and continuously bear with equal force on the cap tops and to adjust themselves for wear of the belt 30 and the friction surface 131. The hinged member 136 is pivotally connected at 138 to the frame 134. Two vertical posts 140 connect the drag shoe 130 to one side of the hinged member 136 and two posts 140 connect the hold down plate 133 to the other side of the hinged member 136. The adjustable screw 135 sets the upper height for the drag shoe 130 and a compressed coil spring 135 is positioned between the frame 134 and the hold down plate 133 to compensate for the upward force of the sealing belt 30 and to cause the belt 30 and the drag shoe 130 to normally engage each cap top with equal force.

The sealing belt 30 is driven by the pulley 44 and passes over two idler rollers 141 and 142 at the entrance end of the sealing unit 8. The tension on the belt 30 is adjusted by the adjustable spring loaded support rod 143 for the upper pulley 142. The belt 30 provides an effective cap rotating force as long as it moves faster than the conveyor 2. Effective sealing action has been obtained when the sealing belt 30 moves at about twice the speed of the conveyor 2 although other speeds are effective.

Where press on caps are being used, the drag shoe 130 is not used and the sealing unit includes a belt of appropriate width to engage the entire cap top surface and preferably driven at the conveyor speed.

Alternative embodiment for use with independently driven conveyor As described above, the present sealing machine includes a support column 11 adjustably mounting the sealing head 9 including the container side belts 4, the cap applicator 7, and the sealing unit 8. This unitary structure makes the machine particularly useful with existing conveyor arrangements since it is merely necessary to locate the support 11 in the proper position with respect to the conveyor and to adjust the height of the various elements with respect to the conveyor as described above.

FIGS. 17, 18 and 19 illustrate an embodiment of the machine wherein a separate drive motor is mounted directly on the sealing head 9 to drive the side belts 4 and the sealing belt 30 and to thus provide a complete sealing unit which may be positioned adjacent to an existing conveyor. FIG. 17 illustrates such a conveyor 2 which may be included as a part of the sealing machine or which may be part of an overall container handling system. A separate drive is provided for such an independent conveyor and in FIG. 17 this separate drive is illustrated as an electric drive motor mounted on a conveyor support 151 having an appropriate speed control unit 152 adjusted by a control handle 153. An output sprocket on the speed control unit 152 is coupled to a sprocket on the conveyor drive shaft 154 by means of a drive chain 155.

FIGS. 18 and 19 illustrate a preferred embodiment for the drive for the sealing machine head 9. This includes a drive motor 156 mounted on the top of the sealing head 9 with a geared output drive box 157 including an output shaft 158. The output shaft 158 is coupled to the drive shaft 43 for the sealing belt pulley 44 (FIG. 17) through the intermediation of sprockets 159 and 160 coupled by a drive chain 161. The side belts 4, as described above, are driven by a horizontal drive shaft 38 through the intermediation of helical gear couplings 37, vertical shafts 39, and end pulleys 17. In this embodiment of the machine, the horizontal drive shaft 38 is driven by the drive motor 156 through the intermediation of a sprocket 162 on the drive shaft 38 coupled to the sprocket 163 on the drive shaft 43 by a chain 164. A11 idler sprocket 165 is adjustably positioned to retain tension on the drive chain 164. Adjustments in the speed of the sealing belt 30 and the side belts 4 for differing conveyor speeds may be made conveniently by choosing sprockets 160 or 163 having the necessary number of teeth.

Since the drive motor 156 is mounted directly on the sealing head 9, it is clear that the height of the sealing head 9 above the conveyor 2 and other necessary adjustments may be made independently of the drive system for the sealing belt and the side belts. A simple and effective sealing machine is provided for use with an existing conveyor system.

Alternate embodiment with a chain driven conveyor As described above, the use of a single adjustable support column 11 for the principal components of the sealing machine makes the use of a drive motor mounted directly on the sealing head 9 advantageous. Another embodiment of the sealing machine is illustrated in FIGS. 20 thru 22 wherein the drive motor 170 for the side belts 30 is mounted on the head 9 for adjustment therewith and where in addiion a preferred embodiment of a chain coupling is employed to drive the conveyor 2 from this same electric motor 170 and in synchronism with the side belts 4 and the sealing belt 30.

The drive motor 170 is coupled to the drive shaft 43 for the sealing belt pulley through the intermediation of the sprockets 171 and 172 and the chain 173. The horizontal drive shaft 38 which is opzratively coupled to the side belts 4 as described above is driven from the shaft 43 through the intermediation of the sprockets 174 (FIG. 22) and 175 and the drive chain 176 tensioned by an idler sprocket 177.

A drive sprocket 178 on the pulley drive shaft 27 for conveyor 2 is coupled to a sprocket 179 on the drive shaft 43 by a chain drive system 180 which compensates for adjustments of the height of the sealing head 9.

The chain system 180 includes a pair of elongated drive chains 181 and 182 having their runs angularly related and having their adjacent ends interconnected at meshed pinions 183 and 184 and sprockets 185 and 186 (FIG. 22). The sprockets and pinions 183 thru 186 are rotatably mounted in the lower end of a guide arm 187 which is pivotally connected to the longitudinal guide arm 188. The upper end of the guide arm 187 is pivotally attached to bracket 189 at 190 and the longiiudinal arm 188 is pivotally mounted on shaft 27 thereby permitting height adjustments to be made of sealing head 9 with corresponding angular changes resulting between the arms 187 and 188 and the related drive chains 181 and 182 and without requiring any other adjustment of the conveyor drive.

It will be seen that a novel sealing machine construction is provided giving high-speed straight line container sealing wih a sealing machine which is both efiicient and compact and which is also characterized by relative simplicity and ease of adjustment. In particular, a straight line sealing machine has been disclosed with a novel head construction wherein the cap applying and sealing means as well as the container gripping side belts and the related drives are incorporated in a unitary adjustably mounted head and wherein simplified adjustments are provided for both container height and width and for handling of caps of varying diameters and skirt depths. These advantages have been incorporated in a structure which also is adapted for vacuum sealing and wherein an effective steam directing and insertion system 10 is provided within the head and wherein the above described adjustments are made without affecting the adjustment of or the operation of the steam system. The sealing machine is adapted for use with existing conveyor systems and may be used with such systems without an attached conveyor of its own.

The sealing machine structure disclosed is also particularly useful for compact installations due to the novel form of its steam chamber wherein effective vacuum sealing is obtained with a tunnel which terminates adjacent to the cap feeding chute and which permits the associated cap feeding hopper and inclined chute to be located immediately adjacent to the end of the tunnel with unobstructed access in a direct path above the conveyor and into the cap applicator.

The improved machine is also characterized by the mounting of container gripping side belts directly onto the vacuum chamber of the machine head whereby the side belts height may be adjusted simultaneously with the adjustment of the cap applicator and the sealing head and wherein these adjustments may be made with the sealing chamber open to permit visual adjustments by the machine operator and with all of the cooperating elements of the machine in their final operating position.

As various changes may be made in the form, con struction and arrangement of the parts herein without departing from the spirit and scope of the invention and without sacrificing any of its advantages, it is to be understood that all matter herein is to be interpreted as illustrative and not in a limi'ing sense.

Having thus described our invention, we claim:

1. In a machine for sealing containers with closure caps having a conveyor for moving containers along a generally straight and horizontal path and including a drive for said conveyor, an improved head comprising the combination of a hollow steam chamber, a unitary support for said chamber including an adjustor for changing the height of the chamber with respect to the conveyor, means for applying caps loosely to the container tops, means for thereafter tightly sealing the containers with the applied caps, belt means including a pair of side belts for gripping the containers on the conveyor, all of the aforesaid means being mounted on said chamber whereby their height is simultaneously changed by said adjustor, said conveyor drive mounted on said chamber and a drive coupling connecting said belt means and said sealing means with said conveyor drive including a plurality of elongated interconnected chains having angularly related runs to compensate for changes of chamber height for automatically compensating for vertical movement of said head by said adjustor.

2. The machine as claimed in claim 1 which further comprises improved side belt support means comprising the combination of a pair of elongated back-up bars, means for mounting said back-up bars in generally parallel relationship on said chamber, a plurality of belt engaging rollers, said rollers being mounted between a plurality of pairs of spaced guide plates, said pairs of guide plates being pivotally coupled together forming elongated roller guides, and said guides being disposed along facing edges of said back-up bars.

3. In a machine for sealing containers with closure caps having a conveyor for moving containers along a generally straight and horizontal path and including a drive for said conveyor, an improved head comprising the combination of a hollow steam chamber, a unitary support for said chamber including an adjustor for changing the height of the chamber with respect to the conveyor, means for lightly screwing caps onto container threads, means including a sealing belt and a drag shoe spaced laterally therefrom for tightly screwing the caps onto the containers, belt means for gripping the containers on the conveyor, all of the aforesaid means and said conveyor drive being mounted on said chamber whereby their height is simultaneously changed by said adjustor, and a drive coupling connecting said belt means and said sealing means with said conveyor drive including a plurality of elongated interconnected chains having angularly related runs and interconnected by meshed pinions and sprocket means for automatically compensating for vertical movement of said head by said adjustor.

4. In a machine for sealing containers with closure caps having a conveyor for moving containers along a generally straight and horizontal path and including a drive for said conveyor, an improved head comprising the combination of a hollow steam chamber, a unitary support for said chamber including an adjustor for changing the height of the chamber with respect to the conveyor, means for lightly applying caps to containers on said conveyor, sealing means for sealing the containers with the applied caps, side belt means for gripping the containers on the conveyor, side belt support means comprising the combination of a pair of elongated back-up bars, means for mounting said back-up bars in generally parallel relationship, a plurality of belt engaging rollers, said rollers being mounted between a plurality of pairs of spaced guide plates, said pairs of guide plates being pivotally coupled together forming elongated roller guides, said guides being disposed along facing edges of said back-up bars, all of the aforesaid means being mounted on said chamber whereby their height is simultaneously changed by said adjustor, a drive coupling connecting said belt means and said sealing means with said conveyor drive including means for automatically compensating for vertical movement of said head by said adjustor, said chamber extending longitudinally of the conveyor from the cap applying means to the sealing means and including steam outlet ports positioned opposite said cap applying means only, and adjustable side covers extending downwardly alongside the conveyor.

5. The machine as claimed in claim 3 in which said belt means comprises a pair of cooperating container gripping side belts, a side belt support means comprising the combination of a pair of elongated back-up bars, means for mounting said back-up bars in generally parallel relationship, a plurality of belt engaging rollers, means for pivotally coupling said rollers together forming elongated roller guides, and said guides being disposed along facing edges of said back-up bars.

6. In a machine for sealing containers having a generally straight and horizontal conveyor belt and a pair of cooperating container gripping side belts, an improved side belt support means comprising the combination of a pair of elongated back-up bars, means for mounting said back-up bars in generally parallel relationship, a plurality of belt engaging rollers, said rollers being mounted be tween a plurality of pairs of spaced guide plates, said pairs of guide plates being pivotally coupled together forming elongated roller guides, and said guides being disposed along facing edges of said back-up bars.

7. In a machine for sealing containers having a generally straight and horizontal conveyor belt and a pair of cooperating container gripping side belts, an improved side belt support means comprising the combination of a pair of elongated back-up bars, means for mounting said backup bars in generally parallel relationship, a plurality of belt engaging rollers, said rollers being mounted between a plurality of pairs of spaced guide plates, each pair of guide plates mounting a plurality of rollers, said pairs of guide plates being pivotally coupled together forming elongated roller guides, and said guides being disposed along facing edges of said back-up bars.

8. A machine as claimed in claim 4 in which said side covers are mounted on the side belt support means.

9. The machine as claimed in claim 4 which includes a cap feed chute comprising an elongated hollow steam chamber including top, bottom and side members, means for adjusting the space between said top and bottom members, a hollow cap support rail on said bottom member for slideably engaging the bottoms of caps, means for admitting steam into said rail, a plurality of steam outlets positioned in said support rail positioned to direct steam against the undersides of the caps, and a hollow steam chamber extending longitudinally of the conveyor at the area where the caps are applied to the containers and having adjustable side covers extending downwardly along the side of the conveyor.

10. A machine as claimed in claim 9 including a hollow cap guide rail on said top member, means for admitting steam into said rail and a plurality of steam outlets in said rail positioned to direct steam against the outside of the cap tops.

11. The machine as claimed in claim 1 in which said cap applying means comprises a magnetic cap leveling plate, and a drag means positioned to engage an off-center portion of the cap tops.

12. The machine as claimed in claim 4 in which said cap applying means comprises a magnetic cap leveling plate, and a drag means positioned to engage an off-center portion of the cap tops.

References Cited UNITED STATES PATENTS 2,352,761 7/1944 Bell 53114 X 2,630,959 3/1953 Brown 53-317 X 2,735,600 2/1956 Hohl et al. 53-110 2,869,300 1/1959 Stover 53313 X 2,942,394 6/1960 Bjering et al. 533l4 3,054,234 9/1962 Stover 53317 X 3,289,383 12/1966 Foss 53110 X 2,768,487 10/1956 Day et al. 53-11 3,274,748 9/1966 Roberts et a1 53--l1 X TRAVIS S. MCGEHEE, Primary Examiner.

US. Cl. X.R. 53314, 317 

